催化作用
制氢
电解质
析氧
水溶液
分解水
氨
氧化物
电化学
氢
乙腈
无机化学
氨生产
化学
化学工程
材料科学
金属
产量(工程)
电解水
过渡金属
电极
法拉第效率
铂金
氧气
生产(经济)
多相催化
商品化学品
反应性(心理学)
作者
Cheolwoo Park,Hyelim Kwak,Tae Sik Koh,Yurim Sohn,Yiseul Park,Geun Ho Gu,Gun‐hee Moon,Wooyul Kim
标识
DOI:10.1002/anie.202522662
摘要
Ammonia oxidation reaction (AOR) offers a promising carbon-free hydrogen production pathway under ambient conditions, yet practical implementation faces critical challenges from catalyst deactivation and competing side reactions in aqueous systems. We present an electrolyte-engineered approach to photoelectrochemical (PEC) AOR that enables both enhanced hydrogen production and reversible catalyst regeneration. By employing a non-aqueous acetonitrile electrolyte at the BiVO4 photoanode, we suppress competing oxygen evolution and NOx poisoning, achieving a 6.9-fold higher hydrogen yield than aqueous systems. Spectroscopic and electrochemical analyses reveal that catalyst deactivation in water is not permanent but dynamically reversible upon re-exposure to nonaqueous environment, emphasizing the solvent-governed interfacial behavior. This electrolyte-engineering approach proves broadly applicable across metal oxide photoanodes (BiVO4, WO3, α-Fe2O3), establishing a universal design principle for PEC AOR systems. Our findings redefine the role of electrolyte composition in governing interfacial pathways and provide a practical framework for developing high-efficiency ammonia-to-hydrogen conversion platforms with enhanced durability and flexibility.
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